US9025353B2 - High voltage high current regulator - Google Patents

High voltage high current regulator Download PDF

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US9025353B2
US9025353B2 US13/253,877 US201113253877A US9025353B2 US 9025353 B2 US9025353 B2 US 9025353B2 US 201113253877 A US201113253877 A US 201113253877A US 9025353 B2 US9025353 B2 US 9025353B2
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current
circuit
voltage
field emission
cold
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US20120081097A1 (en
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Curtis A. Birnbach
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Advanced Fusion Systems LLC
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Advanced Fusion Systems LLC
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Priority claimed from US12/554,818 external-priority patent/US8248740B2/en
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Priority to US14/658,838 priority patent/US20150187501A1/en
Priority to US14/658,794 priority patent/US9711287B2/en
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01GCAPACITORS; CAPACITORS, RECTIFIERS, DETECTORS, SWITCHING DEVICES, LIGHT-SENSITIVE OR TEMPERATURE-SENSITIVE DEVICES OF THE ELECTROLYTIC TYPE
    • H01G4/00Fixed capacitors; Processes of their manufacture
    • H01G4/35Feed-through capacitors or anti-noise capacitors
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05FSYSTEMS FOR REGULATING ELECTRIC OR MAGNETIC VARIABLES
    • G05F1/00Automatic systems in which deviations of an electric quantity from one or more predetermined values are detected at the output of the system and fed back to a device within the system to restore the detected quantity to its predetermined value or values, i.e. retroactive systems
    • G05F1/10Regulating voltage or current 
    • G05F1/12Regulating voltage or current  wherein the variable actually regulated by the final control device is AC
    • G05F1/40Regulating voltage or current  wherein the variable actually regulated by the final control device is AC using discharge tubes or semiconductor devices as final control devices
    • G05F1/42Regulating voltage or current  wherein the variable actually regulated by the final control device is AC using discharge tubes or semiconductor devices as final control devices discharge tubes only
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05FSYSTEMS FOR REGULATING ELECTRIC OR MAGNETIC VARIABLES
    • G05F1/00Automatic systems in which deviations of an electric quantity from one or more predetermined values are detected at the output of the system and fed back to a device within the system to restore the detected quantity to its predetermined value or values, i.e. retroactive systems
    • G05F1/10Regulating voltage or current 
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J19/00Details of vacuum tubes of the types covered by group H01J21/00
    • H01J19/02Electron-emitting electrodes; Cathodes
    • H01J19/24Cold cathodes, e.g. field-emissive cathode
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J19/00Details of vacuum tubes of the types covered by group H01J21/00
    • H01J19/42Mounting, supporting, spacing, or insulating of electrodes or of electrode assemblies
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J19/00Details of vacuum tubes of the types covered by group H01J21/00
    • H01J19/54Vessels; Containers; Shields associated therewith
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J19/00Details of vacuum tubes of the types covered by group H01J21/00
    • H01J19/70Means for obtaining or maintaining the vacuum, e.g. by gettering
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J19/00Details of vacuum tubes of the types covered by group H01J21/00
    • H01J19/82Circuit arrangements not adapted to a particular application of the tube and not otherwise provided for
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J21/00Vacuum tubes
    • H01J21/02Tubes with a single discharge path
    • H01J21/06Tubes with a single discharge path having electrostatic control means only
    • H01J21/10Tubes with a single discharge path having electrostatic control means only with one or more immovable internal control electrodes, e.g. triode, pentode, octode
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J5/00Details relating to vessels or to leading-in conductors common to two or more basic types of discharge tubes or lamps
    • H01J5/02Vessels; Containers; Shields associated therewith; Vacuum locks
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J7/00Details not provided for in the preceding groups and common to two or more basic types of discharge tubes or lamps
    • H01J7/14Means for obtaining or maintaining the desired pressure within the vessel
    • H01J7/16Means for permitting pumping during operation of the tube or lamp
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02HEMERGENCY PROTECTIVE CIRCUIT ARRANGEMENTS
    • H02H3/00Emergency protective circuit arrangements for automatic disconnection directly responsive to an undesired change from normal electric working condition with or without subsequent reconnection ; integrated protection
    • H02H3/08Emergency protective circuit arrangements for automatic disconnection directly responsive to an undesired change from normal electric working condition with or without subsequent reconnection ; integrated protection responsive to excess current
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02HEMERGENCY PROTECTIVE CIRCUIT ARRANGEMENTS
    • H02H9/00Emergency protective circuit arrangements for limiting excess current or voltage without disconnection
    • H02H9/02Emergency protective circuit arrangements for limiting excess current or voltage without disconnection responsive to excess current
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02HEMERGENCY PROTECTIVE CIRCUIT ARRANGEMENTS
    • H02H9/00Emergency protective circuit arrangements for limiting excess current or voltage without disconnection
    • H02H9/08Limitation or suppression of earth fault currents, e.g. Petersen coil

Definitions

  • the present invention relates to a high voltage, high current regulator circuit, with one aspect relating to controlling high current in a circuit, another aspect relating to clamping a high voltage in a circuit, and yet another aspect relating to a vacuum integrated circuit.
  • An “electrical power grid” as used herein means an electrical power and distribution grid for powering private residences, industry and government users.
  • Prior art current fault limiters are typically based on technologies such as insertion of resistance or inductance, which may be conventional or superconducting inductance coils, or the use of solid state devices, such as metal oxide varistors. None of these techniques is capable of meeting the needs of the electric power industry. Currently, the most robust systems under development offer fault current limiting of approximately 50% of maximum rated current, while the electric power industry needs limiting of 80% or more of maximum rated current. Further, prior art technologies are limited in voltage- and current-handling capacity due to the intrinsic nature of their design.
  • Purely resistive current limiting is the oldest and the least efficient method of limiting current. It involves inserting into a current-carrying conductor a series resistance whose value has been calculated to only allow a certain maximum amount of current to flow. Excess current is converted directly to heat, so that efficiency is very low. Resistive current limiting is rarely used in power circuitry since the efficiency is frequently only on the order of 50%.
  • inductive current limiting is somewhat better than resistive current limiting and is, in fact, widely used in the electric power industry.
  • a disadvantage of inductive current limiting is that current is shifted out of phase with the voltage, resulting in a poor power factor.
  • a capacitor is often paired with an inductor to correct the power factor. This becomes problematic on high power systems, since the power handling and voltage-withstand ratings of inductors and capacitors are limited. It is principally this limitation that has driven the present development efforts in the power industry for more reliable and effective current limiting techniques.
  • Solid state devices are also subject to single-arc failures. A single-arc failure is caused when an individual device suffers an electrical breakdown and an arc occurs within the crystal of the semiconductor itself. This damages the crystal, frequently leaves a carbon track, and causes the semiconductor device to stop working.
  • Transient voltages An additional concern regarding electrical power grids are transient voltages, which can be destructive to electrical components in the grid. Transient voltages may arise from various causes, and virtually always arise in the present of a substantial fault current.
  • a need exists for a robust voltage regulator e.g., a voltage-clamping circuit that can operate at high voltage and high current in an electrical power grid or other circuit.
  • the current-regulating circuit comprises at least one main-current carrying cold-cathode field emission electron tube that conducts current between the first and second terminals.
  • the at least one main-current carrying cold-cathode field emission electron tube has first and second control grids for controlling current conduction between the first and second terminals when the voltage on the first and second terminals is positive and negative, respectively.
  • First and second grid-control cold-cathode field emission electron tubes respectively provide control signals for the first and second grids.
  • the foregoing current regulator provides a reliable and effective fault current regulator that can be used in electrical power grids, as well as providing other functions such as described below.
  • a voltage-clamping circuit which may be used independently or used in conjunction with the foregoing current regulator, is interposed between first and second terminals that are connected to an external circuit.
  • the voltage-clamping circuit comprises a bidirectional voltage clamp including at least one cold-cathode field emission electron tube.
  • the bidirectional voltage clamp has a threshold operating voltage.
  • First and second control grids are associated with the at least one cold-cathode field emission electron tube and are receptive of respective control signals for modulating voltage in a main current-conducting path between the first and second terminals.
  • a circuit biases the voltage clamp via the first and second control grids to set the threshold operating voltage.
  • the foregoing voltage-clamping circuit can operate at high voltage and high current in an electrical power grid or other circuits.
  • a preferred embodiment of the present invention uses the foregoing current regulator and voltage clamp in conjunction with each other. It is distinguished from solid-state devices by its extreme resistance to failures due to arcing. In a solid-state device, a single electrical arc will cause a catastrophic failure, while, in mentioned embodiment, the circuit can be made to be highly tolerant to arcing using routine skill in the art based on the present specification.
  • the present embodiment is further distinguished over a solid-state version because it has a substantially broader temperature operating range.
  • performance starts to rapidly decline typically at only about 26 degrees C., as opposed to the mentioned embodiment when using cold-cathode field emission electron tubes, which can successfully operate at temperatures of 650 degrees C. without the use of specially made cooling means.
  • the upper temperature limit for cold-cathode field emission electron tubes occurs at around 760 degrees C., at which point the tube electrodes go in spontaneous thermionic emission and the tube begins to continuously conduct current.
  • Some new semiconductor devices usually based on silicon carbide, can operate at somewhat higher temperatures than silicon-based devices, that is, about 200 degrees C. maximum.
  • Silicon carbide While this is a substantial improvement, it is still substantially lower than the temperature limit for cold-cathode field emission electron tubes, and silicon carbide is still subject to single arc failures, making it almost as vulnerable as silicon-based devices. Silicon carbide is also very expensive and has low individual device voltage and current handling ratings, typically having a voltage rating no higher than about 1500 volts, necessitating the extensive use of series and parallel networks to achieve higher voltage ratings.
  • a single cold-cathode field emission electron tube can be built to handle voltages in excess of one million volts, with current handling capacities measured in hundreds of KiloAmperes, which no known semiconductor device can achieve.
  • a high voltage high current vacuum integrated circuit comprises a common vacuum enclosure.
  • the vacuum enclosure contains (1) at least one internal vacuum pumping means; (2) at least one exhaust tubulation for evacuating the vacuum enclosure and subsequently sealing and separating the vacuum enclosure from at least one external vacuum pump; (3) vacuum-sealed electrically-insulated feedthroughs passing electrical conductors from outside the vacuum enclosure to inside the enclosure while electrically insulating the electrical conductors from the vacuum enclosure and maintaining the vacuum seal; and (4) internal electrical insulation for minimizing the overall size requirement for the vacuum enclosure, and preventing internal electrical short circuits.
  • At least two cold-cathode field emission electron tubes within the vacuum enclosure are configured to operate at high voltage and high current and are interconnected with each other to implement a circuit function.
  • the foregoing high voltage high current vacuum integrated circuit increases system reliability and simplifies installation into a system as compared to the prior art practice of housing of each cold-cathode field emission electron tube in a separate vacuum housing.
  • FIG. 1 is an electrical schematic diagram of a high voltage high current regulator, partly in block form, in accordance with a preferred embodiment of the invention.
  • FIG. 2 is a simplified perspective view, partially cut away, of a bidirectional cold-cathode field emission tetrode tube, or Bi-tron tube, that may be used in the current regulator of FIG. 1 .
  • FIG. 3 is an electrical schematic diagram of a pair of back-to-back cold-cathode field emission tubes that may be used instead of a Bi-tron tube shown in FIGS. 1 and 2 .
  • FIG. 4 is an electrical schematic diagram, partly in block form, of a pair of power transformers, which utilize a current-regulating aspect of the invention for protection from Geomagnetically Induced Currents (GIC).
  • GIC Geomagnetically Induced Currents
  • FIG. 5 is an electrical schematic diagram of circuitry for controlling the current regulators of FIG. 4 when used to protect the transformers from Geomagnetically Induced Currents (GIC).
  • GIC Geomagnetically Induced Currents
  • FIG. 6 is similar to FIG. 4 , but shows a different use of the current-regulating aspect of the invention.
  • FIG. 7 is similar to FIG. 1 , but shows a high voltage high current regulator circuit having both a current regulator circuit, as in FIG. 1 , and a voltage-clamping circuit.
  • FIG. 8 is a simplified, longitudinal cross-sectional view through the central axis of a high voltage high current vacuum integrated circuit, modified to show internal components in the foreground.
  • FIG. 9 is a block diagram of an HVHC VIC and various external vacuum pumps.
  • FIG. 10 is a cross-sectional side view of a portion of a magnetic shield having a penetration for equalizing vacuum on both sides of the shield.
  • FIG. 11 is an enlarged, simplified cross-sectional view taken at the arrows marked FIG. 11 , FIG. 11 in FIG. 8 .
  • FIG. 12 is a perspective view, partially cutaway, of a ferrite low pass filter having an integrated capacitor that may be used in the high voltage high current vacuum integrated circuit of FIG. 8 .
  • Electric power grid means herein an electrical power and distribution grid for powering private residences, industry and government users.
  • an electrical power grid will have a plurality of power generators and a means for transmission of electricity to a plurality of distribution substations, the function of which substations is to distribute power to private residences, industry and government users.
  • fault current means a severe over-current condition.
  • High current means herein greater than 50 Amps.
  • High voltage means herein greater than 400 Volts AC.
  • FIG. 1 shows a high voltage current regulator circuit 10 having first and second terminals 13 and 15 for being interposed in an circuit whose current is to desired to be regulated.
  • current regulator circuit 10 has a high current capacity, where “high current” is defined above.
  • “high current” is defined above.
  • the conductor (unnumbered), the main current-carrying electrodes (called cathanodes) 28 and 29 of the Bi-tron tube 23 and a shunt resistor 47 are used for both positive and negative voltage excursions on the first and second terminals 13 and 15 .
  • the grids 26 and 31 of Bi-iron 23 are respectively used during the positive and negative excursions of voltage on first and second terminals 13 and 15 .
  • the dashed-line loops 18 and 20 preferably are symmetrically arranged with each other, both as to circuit topology and component values, so that a description of only the circuitry associated with dashed-line loop 18 suffices to describe the circuitry associated with dashed-line loop 20 .
  • the circuitry of dashed-line loop 18 includes a bidirectional cold-cathode field emission tube 23 , referred to in abbreviated form herein as a Bi-tron tube.
  • a Bi-tron tube The structure of the Bi-tron tube 23 may be more readily appreciated with reference to FIG. 2 , which shares common part numbers with the Bi-tron 23 if FIG. 1 .
  • Bi-Von tube 23 includes an inner “cathanode” 26 , by which is meant a main current-carrying conductor that alternately functions as a cathode and an anode.
  • Cathanode 26 is cylindrically shaped, and may be in the form of a cylindrical solid as shown.
  • a second cathanode 29 surrounds cathanode 26 and shares the same longitudinal axis (not shown).
  • a cylindrically shaped grid 28 surrounds cathanode 26 , is adjacent to, and associated with, such cathanode.
  • a cylindrically shaped grid 31 is enclosed by cathanode 29 and is adjacent to, and associated with, such cathanode.
  • a high voltage electron tube 35 is included in dashed-line loop 18 , and, in accordance with circuitry to be now described, senses voltage on first terminal 13 and controls grid 31 of Bi-tron 23 .
  • High voltage electron tube 35 also known as a Pulsatron tube, is a cold-cathode field emission tube, having an anode 37 , a cathode 39 and a grid 41 adjacent to, and associated with such cathode 39 .
  • anode 37 , cathode 39 and grid 41 are cylindrically shaped. Further details of a Pulsatron tube are found in U.S. Pat. No. 4,950,962, issued Aug. 21, 1990, entitled High Voltage Switch Tube.
  • First terminal 13 and second terminal 15 are preferably interconnected into an electrical power grid (not shown) in the order of direction of power flow in the electrical power grid.
  • resistor 42 and an adjustable resistor 44 establish a bias voltage for grid 31 of Bi-tron 23 , which functions as a series current regulator.
  • Resistor 42 may have an inductive component as well.
  • Bi-tron 23 is functionally analogous to a FET in this circuit. The current flowing from Bi-tron tube 23 flows through a shunt resistor 47 so as to develop a voltage across such resistor 47 . This voltage is fed through a voltage divider comprised of resistors 50 and 52 .
  • Grid 41 of Pulsatron tube 35 is connected to the junction of resistors 50 and 52 .
  • Reference voltage REF. 1 is applied to the upper side of resistor 50 .
  • the ratio between the voltage of shunt resistor 47 , taken at second terminal 15 , and the reference voltage REF. 1 determines the degree of conduction of Pulsatron tube 35 , which, in turn, controls the conduction of Bi-tron tube 23 .
  • a capacitor 55 connected across resistor 52 , establishes a first time constant with resistor 50 to ensure that the circuit stays in conduction up to the zero-crossing point.
  • High frequency harmonics are undesirable in electric power grids where they lead to system inefficiencies. Considerable effort is expended by the public utility companies to eliminate high frequency harmonics, so any switching component that produces them is of inappropriate design for power grid applications. Reduction of harmonic content in switching operations by high voltage current regulator 10 ( FIG. 1 ) is preferably implemented (1) by increasing the length of the electron gun assemblies formed from cathanodes 26 and 29 as shown in FIG. 2 , and (2) by including a second time constant circuit in each dashed-line loop 18 or 20 in FIG. 1 for controlling Bi-tron 23 .
  • the circuitry within dashed-line loop 18 includes an RC time constant circuit, formed by resistor 42 and capacitor 58 , which has been calculated to produce a risetime on the order of 1 ⁇ 8 of a cycle in a 60 Hz or other typical frequency in an electrical power distribution grid circuit.
  • An alternative time constant circuit uses an inductor in place of resistor 42 , in series with grid 29 of Bi-tron tube 23 .
  • the described time resistor-capacitor (RC) time constant circuit or inductor capacitor (LC) time constant circuit provides the desired slow rise time to minimize harmonics, as described above.
  • Resistor 64 is part of an adjustable voltage divider with adjustable resistor 44 , for setting the grid bias of Pulsatron 35 . Resistor 64 also influences the bias of the associated grid 31 of the Bi-tron tube 23 . A further resistor 66 , shown in phantom lines, may also be used in biasing grid 41 of Pulsatron tube 35 .
  • FIG. 3 shows an alternative to using a bidirectional cold-cathode field emission tube, or Bi-tron tube, 23 in FIG. 1 .
  • FIG. 3 shows a pair of back-to-back, or anti-parallel, connected cold-cathode field emission electron tubes 24 and 25 , so that the anode of tube 24 is at the potential of main-current carrying electrode 27 , which corresponds to cathanode 26 of Bi-tron 23 ( FIG. 1 ) and the anode of tube 25 is at the potential of main current-carrying electrode 30 , which corresponds to cathanode 29 of Bi-tron 23 .
  • Tubes 24 and 25 have respective control grids 33 and 34 , which correspond to control grids 31 and 28 of Bi-tron 23 in FIG. 1 .
  • Electron tubes 24 and 25 preferably have cylindrical electrode geometry, and may comprise Pulsatron tubes, described above.
  • dashed-line loop 20 For operation of high voltage current regulator circuit 10 when the polarity of the voltage on first and second terminals 13 and 15 is negative, the circuitry within dashed-line loop 20 functions in a complementary manner to the above-described circuitry in dashed-line loop 18 .
  • Corresponding components in dashed-line loop 20 have been given corresponding reference numerals, augmented by a leading “ 10 ”; whereby, Pulsatron tube 1135 in lower loop 20 corresponds to Pulsatron tube 35 in upper loop 18 .
  • the high voltage current regulator circuit 10 of FIG. 1 is designed to have one or more of the following features:
  • FAULT CURRENT REGULATOR Fault current limiting is an extremely important technique that can be implemented in many places in an electrical power grid. It can be used to protect individual elements of such a grid, such as circuit breakers and transformers; it can be used as an active control element in so-called “Smart-grids”; and it can be used for protection from Geomagnetically Induced Currents (GIC), discussed as follows.
  • GIC Geomagnetically Induced Currents
  • FIG. 4 shows three-phase transformers 70 and 80 connected between electrical power grid elements 85 and 86 , where the elements are those set forth in the above definition of “electrical power grid.”
  • Transformer 70 has a primary winding 72 with three phases connected in a Delta configuration, and a secondary winding 74 with three phases connected in a Wye configuration.
  • Transformer 80 similarly has a primary winding 82 connected in a Wye configuration and a secondary winding 84 with three phases connected in a Delta configuration.
  • Reference numeral 87 refers to some tangible distance across the surface and upper crust region of the earth, and grounds 88 and 89 are earth grounds.
  • GIC 90 is represented by a series of arrows, and constitute a pseudo DC current. GICs are described in more detail in US Pat. Pub. 2010/0097734 A1 dated Apr. 22, 2010, entitled Method and Apparatus for Protecting Power Systems from Extraordinary Electromagnetic Pulses.
  • FIG. 4 also shows the inclusion of high voltage, high current regulators 91 and 95 in respective ground legs of the Wye-connected windings 74 and 82 of transformers 70 and 80 , attached to earth grounds 88 and 89 , respectively.
  • the current regulators 91 and 95 which may each comprise a high voltage current regulator circuit 10 of FIG. 1 , for instance, act to limit GIC, which is a very low frequency pseudo DC current, or other DC current travelling in the ground legs of the Wye-connected transformer windings. In this way, the transformers 70 and 80 are protected against such pseudo DC or DC fault currents that may readily damage or destroy the transformer.
  • the current regulators 91 and 95 of FIG. 4 are controlled in response to current in the mentioned ground legs for windings 74 and 82 that is measured from the voltage on resistances 92 and 96 of respective high speed current shunts 93 and 97 .
  • the voltages on resistances 92 and 96 are provided a respective DC-AC differentiator circuit 100 of FIG. 5 , for instance, for setting the REF. 1 and REF. 2 reference voltages ( FIG. 1 ) of the current regulators 91 and 95 .
  • Such voltages are preferably transmitted to input terminal 101 of respective FIG. 5 DC-AC differentiator circuits, which control the current regulators in a way so as to allow AC transient currents to simply pass through the current regulators without restriction.
  • the voltages on resistances 92 and 96 are preferably transmitted to input terminals 101 of respective FIG. 5 circuits by respective coaxial connection means 94 and 98 .
  • coaxial connection means 94 and 98 are a fiberoptic link (not shown) with an electrical-to-optical stage at the input end and an optical-to-electrical stage at the output end.
  • the voltages of the resistances 92 and 96 received by respective input terminals 101 of the FIG. 5 circuit, are applied to one input of a differential amplifier 104 , whose other output is connected to ground 105 .
  • a differential amplifier 104 In the presence of a DC, or a pseudo DC current such as characterizes GIC, in the above-mentioned ground legs of transformer windings 74 and 82 , the respective differential amplifiers 104 produce very little output. However, in the presence of transient AC current in the mentioned ground legs, the differential amplifiers 104 respectively produce a sharp spike.
  • a respective Schmidt trigger 106 having one input receiving the output from a differential amplifier 104 and another input at a REF.
  • the other input of the Schmidt trigger 106 is a reference voltage REF. 3 , that is used to set a threshold for causing the Schmidt trigger 106 to send the foregoing described, overriding output voltage on output terminal 103 to allow a high value of transient AC current to pass unhindered through the current regulators 93 and 97 .
  • REF. 3 The lower the threshold that is set by REF. 3 , the larger is the range of transient AC current that is allowed to pass unhindered through the current regulators 93 and 97 .
  • the REF. 1 and REF. 2 reference voltages ( FIG. 1 ) for each of current regulators 91 and 95 operate without override from an output 103 of a respective DC-AC differentiator circuit 100 of FIG. 5 .
  • Differential amplifier 104 and Schmidt Trigger 106 may be implemented with cold-cathode field emission tubes, or with other circuitry that can properly operate at the voltages and current levels that would be encountered. Such voltage and current levels may range upwards of 10 KV, or even 20-30 KV, and may range upwards of 100 KiloAmperes. Implementation of DC-AC differentiator circuit 100 will be routine to those of ordinary skill in the art based on the present specification.
  • FIG. 6 shows an implementation of this application, and is generally similar to FIG. 4 and so uses the same reference numerals for the same parts.
  • FIG. 6 shows the interposition of current regulators 110 , 112 , and 114 , which may each comprise a high voltage current regulator circuit 10 of FIG.
  • the current regulators 110 , 112 , and 114 in the circuit of FIG. 6 may also be used for to remove an over-current condition in an electrical power grid.
  • the high voltage high current regulator circuit 10 of FIG. 1 may advantageously be used to regulate current between first and second terminals 13 and 15 to a zero value in a continuous analog function when desired. In this way, current regulator circuit 10 can be used as a circuit breaker.
  • FIG. 7 shows a current regulator circuit 120 , similar to current regulator circuit 10 of FIG. 1 , and having the same reference numerals as in FIG. 1 to indicate like part for which description in regard to FIG. 7 is thus unnecessary.
  • FIG. 7 also shows a high voltage high current voltage-clamping circuit 130 interposed between the first and second terminals 13 and 15 .
  • a bidirectional cold-cathode field emission electron tube, or Bi-tron tube, 140 of the same description as the above-described Bi-tron tube 23 of FIG. 1 , preferably has its outermost electrode or cathanode 141 , comparable to cathanode 29 of FIG.
  • Bi-tron tube 140 has a threshold operating voltage.
  • a first control grid 142 is associated with outer electrode or cathanode 141 of Bi-tron tube 140
  • a second control grid 144 is associated with inner electrode or cathanode 143 of Bi-tron tube 140 .
  • An external circuit for biasing Bi-tron tube 140 comprising resistor 148 and resistors 152 , 154 and 157 , for instance, are used to set a threshold operating voltage for operation of tube 140 . Selection of component values as well as variations in the biasing circuitry will be routine to those of ordinary skill in the art based on the present specification.
  • a preferably ferrite, first low pass filter 160 may be provided between first terminal 13 and bidirectional current regulator circuit 120 for suppression of transients below the aforementioned threshold operating voltage of Bi-tron tube 140 .
  • the use of a ferrite filter advantageously avoids ferromagnetic resonances in the protected circuit.
  • the mentioned biasing circuit for Bi-tron tube 140 achieves voltage clamping to a predetermined value by selectively bleeding off from excess voltage from first terminal 13 to ground by the shunt configuration in which 140 tube is configured in the circuit of FIG. 7 .
  • a person of ordinary skill in the art will find it routine to design the mentioned biasing circuit for Bi-tron tube 140 in view of the present specification.
  • the voltage-clamping circuit 130 precedes the bidirectional current regulator circuit 120 in the direction of power flow in an electrical power grid. This is because phase angle of current lags 90 degrees behind the phase angle of the voltage, and clamping voltage transients with voltage-clamping circuit 130 may be preferable before regulating current with current regulator circuit 120 . However, voltage-clamping circuit 130 could follow the bidirectional current regulator circuit 120 in the direction of power flow in an electrical power grid.
  • a preferably ferrite, second low pass filter 170 may be used to suppress any transients that may have escaped previous filtering or suppression.
  • Bi-tron tube 140 in voltage-clamping circuit 130 of FIG. 6 is to use the pair of back-to-back, or anti-parallel, connected cold-cathode field emission electron tubes 24 and 25 of FIG. 3 .
  • integration of circuit function would be advantageous with high voltage high current vacuum tube circuits.
  • integration provides a way to provide functional blocks of circuitry as opposed to discrete components, but is distinguished from semiconductor integrated circuits due to often vastly different voltage and current operating regimes, as well as totally different physical manifestations and operating principles.
  • the high voltage current regulator circuit 10 of FIG. 1 is implemented as three separate tubes such as shown, for instance in FIGS. 6E, 12 and 13 of Pub. No. US 2010/0195256 A1 dated Aug. 5, 2010, entitled Method and Apparatus for Protecting Power Systems from Extraordinary Electromagnetic Pulses, which are interconnected in a circuit.
  • a preferred embodiment incorporates at least the cold-cathode field emission electron tubes of FIG. 1 or FIG. 7 into a single stainless steel vacuum enclosure 180 of circular cross-section along its length, or horizontal direction as shown in in FIG. 8 , so as to form a high voltage high current vacuum integrated circuit (HVHC VIC).
  • HVHC VIC high voltage high current vacuum integrated circuit
  • the enclosure 180 may also house low pass filters 160 and 170 , for instance. Since it is difficult to repair electrical components within the vacuum enclosure 180 , it is usually best practice to house only vacuum-tolerant and reliable electrical components within the enclosure. This practice may indicate that some or all of the associated resistors and capacitors shown in FIG. 7 should be located external to the vacuum enclosure.
  • vacuum enclosure 180 also includes conventional chemical getter pumps 240 , 242 , 244 and 246 , which are shown mounted on conventional vacuum-sealed, electrically insulated feedthroughs 241 , 243 , 245 and 247 , respectively.
  • the getter pumps 240 , 242 , 244 and 246 are mounted on one or more internal electrical buses, that are, in turn, connected to one or more conventional vacuum-sealed, electrically insulated feedthroughs.
  • electric vacuum pumps (not shown) within or external to the vacuum enclosure 180 , could be used. The capacity of, and number of, vacuum pumps that will be required for any particular vacuum enclosure is a routine determination to those of ordinary skill in the art.
  • connection can be conventional vacuum sealed, electrically insulated feedthroughs 202 , 204 and 206 for Bi-tron tube 200 , the same type of feedthroughs 212 , 214 and 216 for Bi-tron tube 210 , the same type of feedthroughs 222 , 224 and 226 for Pulsatron tube 220 , and the same type of feedthroughs 232 , 236 and 236 for Pulsatron tube 230 .
  • the various electrical components in vacuum enclosure 180 may be arranged in many different manners.
  • a preferred approach is to have Bi-trons 200 and 210 aligned with each other along their respective longitudinal axes, rather than to be offset from each other as shown in FIG. 8 .
  • a further variation is to use more than one HVHC VIC, each having its own vacuum enclosure for housing fewer than all the parts shown in the circuit of FIG. 7 , for example, which may afford more flexibility in the overall dimensions of all aggregate circuit components.
  • FIG. 8 shows the optional, preferred use electrical potting compound 250 and 252 to provide electrical insulation between conductors of conventional high vacuum electrical feedthroughs in transition regions where electrical leads emerge from the vacuum enclosure 180 .
  • Such potting compounds may be selected from various rubbers and other elastomers, plastics, and ceramics, with ceramics being preferred for highest temperature use.
  • the use of potting compound is strongly preferred.
  • FIG. 9 shows a HVHC VIC 400 , such as shown in FIG. 8 , connected to an external vacuum pump 402 , whose purpose is to maintain the necessary high vacuum within HVHC VIC 400 during operation.
  • FIG. 9 also shows HVHC VIC 400 connected to a large, external vacuum pumping system 406 , whose purpose is to evacuate HVHC VIC 400 during manufacturing, by an exhaust tubulation 404 .
  • the exhaust tubulation 404 is typically a short length of metal pipe.
  • the exhaust tubulation 404 is “pinched off” by a tool (not shown) to provide a robust vacuum seal for both the HVHC VIC 400 and the external vacuum pumping system 406 , as will be routine to persons of ordinary skill from the present specification.
  • a pinched-off exhaust tubulation 404 is shown in the lower right corner of the drawing.
  • multiple electrical components housed within common vacuum enclosure enable multiple circuit functions within HVHC VIC 190 of FIG. 8 .
  • the various electrical connections from electrical components internal to vacuum enclosure 180 to external circuitry or electrical components allows a single, multiple tube HVHC VIC to address differing requirements by only changing the external electrical components.
  • the vacuum enclosure 180 of FIG. 8 also typically includes various electrically insulating mechanical support structures, such as internal magnetic shields 260 , 262 , 264 and 266 , discussed in detail below, and electrical grounding support 275 for Bi-tron 200 .
  • Grounding support 275 is typically provided with vent openings (not shown) for the purpose of improving vacuum conductance and providing pressure equalization within the vacuum enclosure 180 .
  • Enclosure 180 also typically contains many ceramic insulators, such as cylindrically shaped insulator 270 , just within vacuum enclosure 180 .
  • FIG. 8 omits various electrically insulating mechanical support structures and ceramic insulators for clarity of illustration; use of such support structures and insulators will be routine to those of ordinary skill in the art.
  • HVHC VIC 190 By incorporating multiple cold-cathode field emission electron tubes and, preferably, other electrical components within common vacuum enclosure 180 , in a HVHC VIC 190 , installation of the circuitry housed within the enclosure is simplified, and typically requires less space from installation. This reduces the cost of installation, and increases system reliability by reduction of the mean time between failures for the present HVHC VIC.
  • HVHC VIC By implementing multiple circuit functions in the same vacuum enclosure, the present HVHC VIC is somewhat similar to semiconductor circuits. However, the motivation for a HVHC VIC is significantly different from that of a semiconductor integrated circuit (IC). In a semiconductor IC, the primary reason for integration is to increase circuit density. In a VIC, the primary motivation is to increase reliability and simplify installation into a system. HVHC VIC's are primarily intended for use in high voltage, high current, high power electronics circuits, a field in which semiconductors are not able to operate. Similarly, HVHC VIC's are not practical to manufacture for voltages below 400 volts. Below 400 volts, semiconductor devices are more practical.
  • IC semiconductor integrated circuit
  • the claimed invention implements sophisticated circuit functions, responding to different external conditions with different response modes, as previously described.
  • Magnetic shield means a structure including magnetic shielding material formed either (1) fully from magnetic shielding metal, or (2) as a mixture of magnetic shielding metal and non-magnetic material, such as electrically insulating ceramic. A magnetic shield may be covered with electrically insulating material to prevent arcing from high voltages.
  • Magnetic insulation is used interchangeably with the “magnetic shielding material” as defined in the foregoing definition of “magnetic shield.”
  • Electrode insulation means dielectric material such as an electrically insulating ceramic.
  • Electrode and magnetic insulation means a combination of the foregoing-defined “electrical insulation” and “magnetic insulation.”
  • vacuum-grade refers to materials that do not exhibit the property of outgassing; that is, the property of gasses being released from interstitial spaces within the atomic or molecular structure of such material in the presence of reduced pressure and temperature or both reduced pressure and temperature.
  • Thin magnetic material is defined herein as a material where the absolute value of its surface area is substantially greater than the absolute value of its thickness.
  • the vacuum enclosure 180 ( FIG. 8 ) can be formed from high-permeability magnetic shielding metal (not shown), or a liner (not shown) of such material can be interposed between the metallic vacuum enclosure 180 and the ceramic insulator 270 just inside enclosure 180 .
  • high-permeability magnetic shielding metal (not shown)
  • a liner (not shown) of such material can be interposed between the metallic vacuum enclosure 180 and the ceramic insulator 270 just inside enclosure 180 .
  • multiple layers (not shown) of alternating high permeability and low permeability magnetic shielding metals can be used; and for still more enhanced magnetic shielding, electrically and magnetically insulating dielectric material (not shown) can be interposed between the foregoing alternating layers.
  • Enhanced magnetic shielding may also be attained by interposing the foregoing type of dielectric material between layers of material having the same permeability, for instance.
  • the selection of any foregoing techniques, and others, for providing shielding of electrical components within an HVHC VIC from external magnetic fields will be routine to persons of ordinary skill in the art based on the present specification.
  • a design consideration for a HVHC VIC 190 of FIG. 8 is whether the magnetic fields produced by electrical components within common vacuum enclosure 180 , which may be in relatively close proximity to each other, adversely affects operation of other electrical components within such enclosure.
  • Sources for strong magnetic fields may arise from, for instance:
  • the magnetic shields 260 , 262 , 264 and 266 can be used to separate electrical components within vacuum enclosure 180 from one or more other components.
  • the number, geometry, and composition of magnetic shields such as 260 , 262 , 264 and 266 depend on the specific configuration of a desired HVHC VIC, and in particular the spacing interrelationships between internal magnetic field-producing components and internal electron tubes or other components whose operation could be adversely affected by internal magnetic fields.
  • a magnetic shield including magnetic shielding metal in the common vacuum enclosure 180 ( FIG. 8 ) with cold-cathode field emission tubes 200 , 210 , 220 and 230 that can be configured to operate at high voltage, potentially raises the undesirable problem of internal electrical arcing and component failure.
  • an electrical insulator such as electrically insulating ceramic or other refractory material of appropriate dielectric strength and thickness.
  • FIG. 10 shows a portion of a magnetic shield 280 , having vertically extending high permeability magnetic shielding metal 282 and a tubular shaped high permeability magnetic shielding metal 284 , preferably joined together at locations 286 and 288 by welding and annealing, and then encapsulated in an electrically insulating ceramic 290 .
  • the ceramic 290 is formed as a fillet for purposes of reducing stress due to a concentration of the electric field.
  • Magnetically shielded tube 295 provides venting and pressure equalization within the vacuum enclosure 180 ( FIG. 8 ), and would be located preferably close to chemical getter vacuum pumps for optimal vacuum pumping.
  • Magnetically shielded tube 295 preferably has an aspect ratio defined by the ratio of its internal diameter to its length being one to four or greater. This aspect ratio arises from the way in which magnetic field lines flow around an aperture in a tubular structure. By maintaining this ratio, the magnetic shielding properties of the shield wall, through which the tube passes, are maintained.
  • One or more magnetically shielded tubes 295 are required to assure uniform vacuum within vacuum enclosure 180 as shown in FIG. 8 , although they are not shown in FIG. 8 for simplicity.
  • Magnetic shielding metal 282 and 284 is preferably all metal, but could instead be formed of a mixture of high concentration, finely divided magnetic shielding metal in high concentration with an electrically insulating ceramic, which is then molded into a desired shape, encapsulated in electrically insulating ceramic 290 , and then fired to sinter and harden the ceramics.
  • the initial finely divided ceramic particles and the encapsulating ceramic have the same chemical composition, to minimize thermal expansion mismatch.
  • the firing of the outer ceramic and, optionally of any interior composite ceramic and magnetic material preferably performs the additional function of annealing the magnetic shield metal to develop its full shielding potential.
  • External Magnetic Shielding includes variations from using a single layer of high permeability magnetic shielding metal for magnetic shielding. Such variations apply as well to internal magnetic shielding, so that the high permeability magnetic shielding metals 282 and 284 of FIG. 10 could be replaced with alternating layers of high permeability and low permeability magnetic shielding metals, by way of example.
  • the selection of appropriate magnetic shielding metals will be routine to those of ordinary skill in the art based on the present specification.
  • FIG. 11 shows a better view of magnetic shield 266 of FIG. 8 , which has a Y-shape in cross section, which may be an electrical insulator such as electrically insulating ceramic 267 over magnetic shielding metal 268 such as pure or mixed magnetic metal, similar to magnetic shield 280 in FIG. 11 as described above.
  • the magnetic shielding metal 268 is attached to vacuum enclosure 180 by welding when the vacuum enclosure is stainless steel or other electrically conductive metal, and, as shown in FIG. 8 , is also attached to the magnetic shielding material of the adjacent magnetic shields 262 and 264 .
  • the inner magnetic shielding material for magnetic shields 260 , 262 and 264 shown with metal cross-hatching are welded to the vacuum enclosure 180 when the vacuum enclosure is stainless steel or other electrically conductive metal.
  • Bi-tron tube 210 and Pulsatron tubes 220 and 230 are shown as simple circles, and many other structures are omitted for clarity.
  • FIGS. 8 and 10 thus show that each of Bi-tron tubes 200 and 210 , Pulsation tubes 220 and 230 , and low pass filters 193 and 195 are separated from each other by associated electrically and magnetically insulated shields 260 , 262 , 264 and 266 , and each may be considered to be in its own internally electrically and magnetically insulated compartment.
  • more than one internal electrical component can exist in the same internally electrically and magnetically insulated or electrically insulated compartment if the magnetic field from one component does not adversely affect operation of the other components, and so forth.
  • low passfilters 193 and 195 are shielded from other electrical components within vacuum enclosure 180 of HVHC VIC 190 of FIG. 8 by magnetic shields 260 , 262 and 264 .
  • An alternative or additional way of magnetically shielding low pass filters 193 and 195 is now described in connection with FIG. 12 .
  • FIG. 12 shows a preferred construction of a combined low pass filter 300 .
  • a ferrite filter sleeve 303 is placed on a conductor 305 , and forms the inner plate of a bypass capacitor, as well as providing a blocking function for high frequency signals.
  • An outer tubular electrode 307 forms the outer plate of the bypass capacitor.
  • a respective low pass filter 300 provides the filtering described above for each of low pass filters 160 and 170 of FIG. 7 .
  • Additional or alternative RF filtering components may be incorporated in the vicinity of the illustrated low pass filters 193 and 195 in FIG. 8 , which implement low pass filters 160 and 170 of FIG. 7 , respectively.
  • Low pass filter 300 includes grounding spokes 309 . Although not shown in the figures, grounding spokes 309 can attach to the vacuum enclosure 180 ( FIG. 8 ) or another grounded structure, preferably in such a way as to beneficially provide both electrical grounding and mechanical support for low pass filter 300 .
  • outer tubular electrode 307 can be formed of magnetic shielding metal, such as mu metal.
  • the low pass filter 300 acts to magnetically shield other electrical components within vacuum enclosure 180 ( FIG. 8 ) from magnetic fields generated by low pass filters 193 and 195 .
  • the right and left-shown ends of the outer tubular electrode 307 should each extend beyond ferrite filter sleeve 303 so as to restrict the angle of emission of magnetic fields from within outer tubular electrode 307 .
  • magnetic shields 260 , 262 and 264 in FIG. 8 provide significant mechanical support to various internal electrical components. For instance, various of the electrically insulated feedthroughs, such as 212 and 214 , through various of the electrically insulated magnetic shields, e.g., 260 , 262 and 264 , and are advantageously mechanically supported by such shields.

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US12/359,198 US7916507B2 (en) 2008-01-24 2009-01-23 High voltage electron tube inverter with individual output phase current control
US12/554,818 US8248740B2 (en) 2008-09-19 2009-09-04 High speed current shunt
US39003110P 2010-10-05 2010-10-05
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CA2938102A1 (en) 2012-04-12
CA2809883A1 (en) 2012-04-12
EP2625581A4 (en) 2016-02-17
JP2016146744A (ja) 2016-08-12
JP2016146745A (ja) 2016-08-12
EP3156874B1 (en) 2020-12-16
EP2625581B1 (en) 2018-05-16
NZ625923A (en) 2014-08-29
ES2683772T3 (es) 2018-09-27
CA2938102C (en) 2018-11-27
JP5908913B2 (ja) 2016-04-26
NZ626968A (en) 2016-01-29
KR20140001857A (ko) 2014-01-07
NZ607599A (en) 2014-07-25
BR112013007799A2 (pt) 2016-06-07
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US20150187531A1 (en) 2015-07-02
CA2809883C (en) 2016-10-04

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